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The pathway, known as the chromatin remodeling pathway, is responsible for the "unwrapping" of coiled strands of DNA, which must occur before a gene can act or be "expressed." When it is disrupted, certain genes for inflammatory proteins get stuck "on," and the inflammation makes lung tissue degenerate and scar, Kohane explains. (Although the lungs are uniquely vulnerable, he speculates that other tissues in the newborn are also affected.)
The pathway has also been shown to be involved in COPD, the collective term for chronic bronchitis and emphysema, which obstruct airflow and make breathing difficult. A group of drugs known as histone deacetylase inhibitors are directed at this pathway, and are being developed as a treatment for COPD1. Kohane speculates that they might also prevent or treat BPD.
"If you can prevent that pathway from being switched on and chewing away the lung, you might prevent BPD and perhaps improve the rocky clinical course of premature newborns," he says.
In addition, interrupting this inflammatory process might not only slow or halt infants' progression to BPD directly, but could also avoid the need for them to be on the ventilator for prolonged periods, notes Cohen, the study's first author. Very premature infants usually require mechanical ventilation to stay alive -- yet this life-saving measure ironically contributes to the development of BPD.
"This is just the first stage, but if we can target a therapy we can use right when the babies are born, we could limit time on the ventilator and actually prevent disease rather than just treating it," says Cohen, now a neonatologist at Brigham and Women's Hospital (BWH) in Boston.
Interestingly, the researchers didn't find any particular gene to have a different pattern of activity in the infants with BPD. "No single gene turned 'on' or 'off' in a statistically different way between the two groups," says Kohane. "We thought perhaps the study had not worked --- until we realized that it might be an entire pathway that is differentially expressed."
He cautions, however, that a larger sample size is needed to validate the genetic findings as a reliable predictor of BPD in premature infants. To confirm the results, Cohen and colleagues at BWH will do follow-up studies with additional umbilical cord samples, and will also look at gene expression in cells from lung fluid to see if expression differs over time.
Corroborating other studies, Kohane and Cohen also found that infants born at younger gestational ages (whether or not they developed BPD) had reduced activity of pathways involved in converting nutrients into energy, a possible explanation for why premature infants require high-calorie intravenous feeding after birth.
Finally, the study validates the hypothesis that the umbilical cord makes a good proxy for studying fetal lung physiology. Unlike lung tissue, umbilical cord tissue is readily available to researchers, contains stem cells for many fetal tissues, and appears to reflect the physiology of the fetus and the intrauterine environment.
The study was funded by the National Institutes of Health and Robert P. and Judith N. Goldberg Foundation. Citation is as follows:
Perturbation of Gene Expression of the Chromatin Remodeling Pathway in Premature Newborns at Risk for Bronchopulmonary Dysplasia.
Jennifer Cohen, Linda J Van Marter, Yao Sun, Elizabeth Allred, Alan Leviton and Isaac Kohane.
Genome Biology 2007 (in press).
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